Mussel-inspired dual-superlyophobic biomass membranes for selective oil/water separation
Dual-superlyophobic membranes that exhibit underwater superoleophobicity and underoil superhydrophobicity concurrently have gained considerable attention for oil/water separation. To effectively treat oily wastewater, consistent efforts have been made to develop fast and simple methodologies with lo...
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sg-ntu-dr.10356-1547272022-01-05T06:58:58Z Mussel-inspired dual-superlyophobic biomass membranes for selective oil/water separation Mai, Van Cuong Das, Paramita Zhou, Jiajing Lim, Teik Thye Duan, Hongwei School of Chemical and Biomedical Engineering Nanyang Environment and Water Research Institute Engineering::Chemical engineering Biomass Dual-Superlyophobicity Dual-superlyophobic membranes that exhibit underwater superoleophobicity and underoil superhydrophobicity concurrently have gained considerable attention for oil/water separation. To effectively treat oily wastewater, consistent efforts have been made to develop fast and simple methodologies with low cost, environmentally friendly materials. Here, the dual-superlyophobic membranes are obtained based on one-step tailored growth of mussel-inspired polydopamine (PDA) nanoparticles on the surfaces of biomass membranes. The results demonstrate that the universal adhesion of PDA allows the modification of biomass fibers of different surface hydrophobicity. The oxidation polymerization of dopamine leads to the rapid growth of PDA nanostructures, which form stable coatings of high roughness instead of homogeneous conformal coatings generated in the conventional synthesis of PDA. The amphiphilic nature of PDA and the rough surfaces imparted by the PDA nanostructures collectively lead to dual-superlyophobic properties. Membranes of the coated biomass fibers prewetted by either water or oil become impermeable to the counterpart liquids, giving rise to efficient oil–water separation in a broad spectrum of mixtures. In particular, the membranes derived from cotton or kapok fibers show oil/water separation efficiencies of above 99.98%, fluxes ranging from 4000 to 22 200 L m−2 h−1, and robust performance for regeneration and repeated uses. 2022-01-05T06:58:58Z 2022-01-05T06:58:58Z 2020 Journal Article Mai, V. C., Das, P., Zhou, J., Lim, T. T. & Duan, H. (2020). Mussel-inspired dual-superlyophobic biomass membranes for selective oil/water separation. Advanced Materials Interfaces, 7(6), 1901756-. https://dx.doi.org/10.1002/admi.201901756 2196-7350 https://hdl.handle.net/10356/154727 10.1002/admi.201901756 2-s2.0-85078681946 6 7 1901756 en Advanced Materials Interfaces © 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. All rights reserved. |
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Engineering::Chemical engineering Biomass Dual-Superlyophobicity Mai, Van Cuong Das, Paramita Zhou, Jiajing Lim, Teik Thye Duan, Hongwei Mussel-inspired dual-superlyophobic biomass membranes for selective oil/water separation |
| description |
Dual-superlyophobic membranes that exhibit underwater superoleophobicity and underoil superhydrophobicity concurrently have gained considerable attention for oil/water separation. To effectively treat oily wastewater, consistent efforts have been made to develop fast and simple methodologies with low cost, environmentally friendly materials. Here, the dual-superlyophobic membranes are obtained based on one-step tailored growth of mussel-inspired polydopamine (PDA) nanoparticles on the surfaces of biomass membranes. The results demonstrate that the universal adhesion of PDA allows the modification of biomass fibers of different surface hydrophobicity. The oxidation polymerization of dopamine leads to the rapid growth of PDA nanostructures, which form stable coatings of high roughness instead of homogeneous conformal coatings generated in the conventional synthesis of PDA. The amphiphilic nature of PDA and the rough surfaces imparted by the PDA nanostructures collectively lead to dual-superlyophobic properties. Membranes of the coated biomass fibers prewetted by either water or oil become impermeable to the counterpart liquids, giving rise to efficient oil–water separation in a broad spectrum of mixtures. In particular, the membranes derived from cotton or kapok fibers show oil/water separation efficiencies of above 99.98%, fluxes ranging from 4000 to 22 200 L m−2 h−1, and robust performance for regeneration and repeated uses. |
| author2 |
School of Chemical and Biomedical Engineering |
| author_facet |
School of Chemical and Biomedical Engineering Mai, Van Cuong Das, Paramita Zhou, Jiajing Lim, Teik Thye Duan, Hongwei |
| format |
Article |
| author |
Mai, Van Cuong Das, Paramita Zhou, Jiajing Lim, Teik Thye Duan, Hongwei |
| author_sort |
Mai, Van Cuong |
| title |
Mussel-inspired dual-superlyophobic biomass membranes for selective oil/water separation |
| title_short |
Mussel-inspired dual-superlyophobic biomass membranes for selective oil/water separation |
| title_full |
Mussel-inspired dual-superlyophobic biomass membranes for selective oil/water separation |
| title_fullStr |
Mussel-inspired dual-superlyophobic biomass membranes for selective oil/water separation |
| title_full_unstemmed |
Mussel-inspired dual-superlyophobic biomass membranes for selective oil/water separation |
| title_sort |
mussel-inspired dual-superlyophobic biomass membranes for selective oil/water separation |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/154727 |
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1722355309069991936 |